Multi-valued on-die termination

ABSTRACT

An integrated circuit memory device stores a plurality of digital values that specify respective termination impedances. The memory device switchably couples respective sets of load elements to a data input/output (I/O) to apply the termination impedances specified by the digital values, including, applying a first termination impedance to the data I/O during an idle state of the memory device, applying a first one of two non-equal termination impedances to the data I/O while the memory device receives write data in a memory write operation and applying a second one of the two non-equal termination impedances to the data I/O while another memory device receives write data in a memory write operation. When outputting read data via the data I/O in a memory read operation, the memory device switchably couples to the data I/O at least a portion of the load elements included in the sets of load elements.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 13/480,298, filed May 24, 2012 and entitled “Controlling On-Die Termination in a Dynamic Random Access Memory Device,” which is a continuation of U.S. patent application Ser. No. 13/180,550, filed Jul. 12, 2011 and entitled “Controlling Dynamic Selection of On-Die Termination” (issued as U.S. Pat. No. 8,188,762), which is a continuation of U.S. patent application Ser. No. 13/043,946, filed Mar. 9, 2011 and entitled “Integrated Circuit Device with Dynamically Selected On-Die Termination” (issued as U.S. Pat. No. 8,089,298), which is a continuation of U.S. patent application Ser. No. 12/861,771, filed Aug. 23, 2010 and entitled “A Memory Controller That Controls Termination in a Memory Device” (issued as U.S. Pat. No. 7,924,048), which is a continuation of U.S. patent application Ser. No. 12/507,794, filed Jul. 22, 2009 and entitled “Memory-Module Buffer with On-Die Termination” (issued as U.S. Pat. No. 7,782,082), which is a continuation of U.S. patent application Ser. No. 12/199,726, filed Aug. 27, 2008 and entitled “Controlling Memory Devices That Have On-Die Termination” (issued as U.S. Pat. No. 7,602,209), which is a continuation of U.S. patent application Ser. No. 11/422,022, filed Jun. 2, 2006 and entitled “Integrated Circuit with Graduated On-Die Termination” (issued as U.S. Pat. No. 7,486,104). Each of the foregoing applications is hereby incorporated by reference.

TECHNICAL FIELD

The present invention relates to high-speed signaling systems and components.

BACKGROUND

High-speed signal lines are commonly terminated by resistive loads selected to match the characteristic impedance of the signal lines and thereby cancel undesired reflections. Historically, the terminating elements have been implemented by discrete resistors connected to metal traces on a mother board or other printed circuit board. More recently, particularly in the domain of high-bandwidth memory systems, on-die termination structures have been provided, for example, on the integrated circuit die of a memory device or memory controller.

FIG. 1 illustrates a prior-art memory system 100 that employs an on-die termination scheme. The memory system 100 includes a memory controller 101 and pair of memory modules 103A and 103B, with each memory module coupled in parallel to a shared data path 102 (DATA), and each memory module (103A, 103B) coupled to a termination control line (TC1, TC2, respectively) to enable receipt of respective termination control signal from the memory controller. As shown in detail view 106, each of the memory devices 105 within a given memory module 103 includes a set of data input/output (I/O) circuits 107 ₁-107 _(N) having a data signal transceiver 109 (i.e., output driver and signal receiver coupled to provide inbound data to and receive outbound data from I/O logic/memory core circuitry 115) and a switched termination structure 111 coupled in parallel to a respective data line 117 ₁-117 _(N) of data path 112 (Data[N:1]), where data lines 117 ₁-117 _(N) of data path 112 constitutes a subset of the data lines within data path 102. The switched termination structures 111 themselves each include a respective load element (R) coupled to the corresponding data line via a switch element (X), with each of the switch elements within the memory devices of a given memory module 103 coupled to a common termination control input, TC, to receive an incoming termination control signal. By this arrangement, the memory controller 101 may assert the termination control signal supplied to either of the memory modules 103 (i.e., via termination control lines TC1 and TC2) to switchably connect the load elements within the constituent memory devices of the memory module to respective lines of the data path 102. During write operations in which data is output onto the data path 102 to be received within a selected one of the memory modules (103A or 103B), the memory controller 101 asserts a termination control signal on the termination control line coupled to the non-selected memory module, thereby terminating the data path stub coupled to that memory module and suppressing undesired reflections. At the same time, the memory controller 101 deasserts the termination control signal supplied to the selected memory module thereby isolating the data path 102 from the on-die terminations within the memory devices 105 of that memory module to avoid undue signal attenuation. This operation of the memory controller is shown at 120 of FIG. 1.

Analysis shows that, unfortunately, the single-termination scheme of FIG. 1 may yield sub-optimal signaling performance due, at least in part, to impedance discontinuity that tends to result at the selected memory module when the on-die terminations within that module are decoupled from the data path 102. On the other hand, asserting the termination control signal at the selected memory module tends to unduly attenuate the incoming data signals, reducing signaling margin and increasing the likelihood of signaling errors.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which like reference numerals refer to similar elements and in which:

FIG. 1 illustrates a prior-art memory system that employs an on-die termination scheme;

FIG. 2 illustrates an embodiment of a memory system having multiple, graduated on-die terminations per high-speed signaling line;

FIG. 3 illustrates an exemplary approach for achieving graduated termination within a memory system without adding additional termination structures within the constituent memory devices;

FIG. 4 illustrates an alternative embodiment of a memory system having graduated on-die terminations;

FIG. 5 illustrates another embodiment of a memory system having graduated on-die terminations; and

FIG. 6 illustrates an exemplary state diagram of a finite state machine that may be applied within a memory device in combination with explicit or implicit termination control detection circuitry to effect a desired one of multiple, graduated terminations.

DETAILED DESCRIPTION

Signaling systems having improved signaling characteristics that result from multiple, graduated on-die terminations are disclosed in various embodiments. In one embodiment, each memory device within a multiple-module memory system includes multiple on-die termination structures per incoming high-speed signal line to enable any of multiple different termination loads to be switchably coupled to the signal line according to whether the memory module is a destination for incoming signals. For example, in a particular embodiment, each memory device within a two-module memory system includes two termination structures per incoming data line, with the load elements within the two termination structures being implemented by or programmed to have different impedance values, thereby enabling selection between a relatively high-load termination and a relatively low-load termination within a given memory module according to whether the memory module is the destination for high-speed signals. Thus, during a write operation, the high-load terminations, referred to herein as hard terminations, may be switchably connected to the high-speed signaling lines within the memory devices of the non-selected (e.g., non-addressed) memory module to provide transmission line load-matching, while the low-load termination, referred to herein as a soft termination, may be switchably connected to the high-speed signaling lines within the memory devices of the selected memory module to provide a desired level of energy absorption (e.g. to cancel reflections) without unduly attenuating the incoming signals. In a subsequent write operation directed to the alternate memory module, the termination selections may be quickly reversed to establish soft termination at the alternately selected memory module and hard termination at the non-selected memory module.

In one embodiment, multiple termination control lines are provided for each rank of memory devices on a memory module (a rank of memory devices being a set of one or more memory devices that are selected to receive or output data as a parallel group) to enable independent selection between soft and hard terminations therein. In an alternative embodiment, a snoop logic circuit is provided within each of the memory devices to determine whether the memory device is the target of a particular signaling transaction and to switchably couple either the soft terminations or the hard terminations to the data lines and/or other high-speed signal lines accordingly. In another embodiment, a buffer integrated circuit (IC) is provided to receive incoming signals within a memory module and to distribute the signals to one of multiple ranks of memory devices on the memory module. In such an embodiment, multiple, graduated on-die termination structures per high-speed signaling line may be provided on the buffer IC instead of, or in addition to, the memory devices. The high-speed signal lines coupled to the multiple, graduated on-die termination structures may include data signal lines, address signal lines, command signal lines (any or all of which may be time multiplexed and thus constitute a single set of signal lines) or any combination thereof. Further, a non-volatile memory such as a serial presence detect (SPD) memory may be programmed with information indicating whether the memory devices within a given memory module include support for graduated terminations. By this arrangement, a memory controller may read the SPD memory (or other characterizing circuit or storage) to determine whether graduated terminations are supported and, if so, issue termination control signals accordingly, thus enabling the memory controller to operate in either a legacy termination mode or graduated termination mode. Also, in a system having dual-rank memory modules, the termination values for each of the two ranks on a given memory module may be programmed to have low-load and high-load values, thus enabling selection between hard and soft terminations according to whether the module is the destination for high-speed signals. These and other embodiments are described in further detail below.

FIG. 2 illustrates an embodiment of a memory system 150 having multiple, graduated on-die terminations per high-speed signaling line. The memory system 150 includes a memory controller 151 coupled to two memory modules, 153A and 153B via a multi-drop data path 152 (i.e., the memory modules 153A and 153B are coupled in parallel to the data path 152), though additional memory modules may be coupled to the multi-drop data path 152 in alternative embodiments. Also, one or more additional signal paths (not shown) for conveying command, address and timing signals may be coupled between the memory controller 151 and memory modules 153.

Each of the memory modules 153 includes multiple integrated-circuit memory devices 155 coupled to respective subsets of signal lines of the data path (i.e., coupled to respective slices of the data path 152), thereby forming a memory rank. In general, the memory devices within the memory rank are accessed as a group, thus enabling transfer of N×M-bit wide read and write data words, where N is the number of data bits conveyed to or from a given memory device in a given transaction (i.e., the slice width), and M is the number of memory devices within the memory rank (i.e., the number of data path slices).

In contrast to the memory devices of FIG. 1, described above, each of the memory devices 155 within memory modules 153 includes two termination control inputs to enable reception of two independent termination control signals and thus provide for switched connection of one of two graduated termination loads (i.e., termination loads having different impedance values) to each data line of the incoming data slice. In the particular embodiment shown, termination control signals are output from the memory controller 151 on termination control lines, TC1 and TC2, that are coupled respectively to termination control inputs, TCa and TCb, of memory module 153A and, in reverse order, to termination control inputs TCb and TCa of memory module 153B. Within each of the memory modules 153, the TCa and TCb termination control inputs are coupled to corresponding TCa and TCb inputs of the individual memory devices 155. Referring to detail view 156, each of the memory devices 155 within a given module 153 includes a set of data I/O circuits 157 ₁-157 _(N) having a data transceiver structure 159 (e.g., output driver 160 a and signal receiver 160 b coupled to provide inbound data to and receive outbound data from I/O logic and memory core 165) and a pair of switched termination structures 161 a and 161 b all coupled in parallel to a respective data line 167 ₁-167 _(N) of data path 162, where data lines 167 ₁-167 _(N) of data path 162 constitute a subset of the data lines within overall data path 152. Each of the switched termination structures 161 a, 161 b includes a respective load element R1, R2 coupled to the corresponding data line via a corresponding switch element X1, X2. As shown, the switch elements X1 within each of the data I/O circuits 157 ₁-157 _(N) is coupled in common to termination control input TCa and the switch elements X2 are coupled in common to termination control input TCb. By this arrangement, when a termination control signal is asserted on signal line TC1, load elements R1 are switchably coupled to respective lines of the data path 152 within module 153A, and load elements R2 are switchably coupled to the respective lines of the data path within module 153B (i.e., by virtue of the swapped coupling of lines TC1/TC2 to the TCa and TCb inputs of the two memory modules 153A and 153B). Thus, by programming (or implementing) load elements R1 to have a relatively high load (i.e., a relatively low impedance) and load elements R2 to have a relatively low load (i.e., a relatively high impedance) within each of the memory devices 155, load elements R1 may be switchably coupled to the data path to effect a hard termination and load elements R2 may be switchably coupled to the data path to effect a soft termination. Accordingly, as shown by the controller operation at 170, during a write operation directed to memory module 153A, the memory controller 151 may assert a termination control signal on line TC2 (and deassert the termination control signal on line TC1) to switchably couple load elements R1 to the data path 152 within memory module 153B and to switchably couple load elements R2 to the data path 152 within memory module 153A, thus effecting a graduated termination within the selected and non-selected memory modules; that is, a soft termination in the selected memory module and a hard termination in the non-selected memory module (note that a third control state may be established by deasserting both termination control signals, thus decoupling termination loads from the data path 102 within both memory modules). When compared with the conventional on/off termination scheme described above in reference to FIG. 1, the multiple, graduated terminations generally yield larger signaling margins (i.e., more open data eyes), thus providing reduced bit error rate and additional headroom for increased signaling rates.

Still referring to FIG. 2, it should be noted that the termination structures 161 a and 161 b may alternatively be included within output driver 160 a, in which case the output driver 160 a may turn on a subset of the elements used to drive the signal line (e.g., a weaker subset of drive elements the full set used when actually driving a signal) and concurrently couple pull-up and/or pull-down termination elements to the signal line at the same time to establish the termination. Also, while a single pair of termination control lines are shown in FIG. 2 and described above (i.e., coupled to the termination control inputs TCa and TCb of memory module 153A and in reverse order to the termination control inputs of memory module 153B), a separate pair of termination control lines may be provided to each memory module in an alternative embodiment.

FIG. 3 illustrates an exemplary approach for achieving graduated termination within a memory system 200 without adding additional termination structures within the constituent memory devices. As shown, the memory system 200 includes a memory controller 201 coupled to two dual-rank memory modules, 203A and 203B, via a multi-drop data path 152 (though additional dual-rank memory modules 203 may be coupled to the multi-drop data path 152 in alternative embodiments and additional ranks may be provided per memory module), but with only one termination control line provided per memory rank, instead of multiple termination control lines per memory rank as in the embodiment of FIG. 2. Because the two ranks (207 ₁ and 207 ₂) of memory devices 205 within a given memory module 203 are coupled in parallel to the data path 152, and the impedance of the relatively short path between them (208) is relatively small as compared to the off-module portion of the data path 152, the termination structures (or load elements thereof) within corresponding memory devices 205 within the two different ranks 207 ₁ and 207 ₂ may be programmed to have (or implemented with) different impedance values, and thus provide for selection between graduated termination loads. More specifically, as shown at detail views 216 a and 216 b, in each of the memory devices 205A within memory rank 207 ₁ of module 203A may be programmed to have a relatively high termination load, R1 (i.e., low impedance) and each of the memory devices 205B within memory rank 2 of memory module 203A may be programmed to a relatively low termination load, R2, thus establishing a soft-terminated memory rank 207 ₁ and a hard-terminated memory rank 207 ₂ within the same memory module. Note that this arrangement is possible even within memory devices 205 that have a single termination structure (i.e., with switch X and termination load coupled in parallel with signal transceiver 159 within an I/O circuit 211) per incoming data line 214, and that the programming of soft and hard termination loads (R1 and R2) within the devices of the different memory ranks may be achieved through register programming (e.g., storing a value within register 221 within the I/O logic and memory core 219), production-time configuration (e.g., fuse, anti-fuse, non-volatile storage element, etc.) or external contact strapping. The memory devices 205 within the two memory ranks 207 ₁ and 207 ₂ of memory module 203B may be programmed in the same manner as shown in detail views 216 c and 216 d. By this arrangement, instead of deasserting termination the control signals supplied to a memory module selected to receive write data, the termination control signal that controls switched coupling of the soft-terminated memory rank 207 ₂ of the selected memory module 203 may be asserted, and the termination control signal that controls switched coupling of the hard-terminated memory rank 207 ₁ deasserted to establish a soft termination at the selected memory module 203, while the termination control signals supplied to the non-selected memory module are oppositely asserted and deasserted (i.e., asserting the termination control signal to engage the hard termination at memory rank 207 ₁ and deasserting the termination control signal to disengage (decouple) the soft termination at memory rank 207 ₂) to establish a hard termination at the non-selected memory module. Accordingly, as shown by the controller operation at 230, in a write operation directed to memory module 203A (memory module A), termination control signals are deasserted on termination control lines TC1 and TC4 (i.e., set to logic ‘0’) and asserted on termination control lines TC2 and TC3 (set to logic ‘1’) to switchably couple the R2 termination loads within memory rank 207 ₂ of memory module 203A to the data path 152 (and switchably decouple the R1 termination loads within memory rank 207 ₁) to effect soft-termination for the selected memory module, and switchably coupling the R1 termination loads within memory rank 207 ₁ of memory module 203B to the data path 152 to effect hard termination for the non-selected memory module. In a write operation directed to memory module 203B, the signal levels on the termination control lines are inverted to establish soft termination (TC3=0, TC4=1) in the selected memory module 203B, and hard termination (TC1=1, TC2=0) in the non-selected memory module 203A.

In an alternative approach to that shown in FIG. 3, hard termination may be achieved by asserting both the termination control signals provided to a given memory module, in effect switchably coupling the load elements within commonly coupled termination structures of the two memory ranks 207 ₁ and 207 ₂ in parallel to establish an impedance R1*R2/(R1+R2) which, when R1 and R2 are programmed to (or implemented with) the same value, becomes R1/2. Thus, in such an approach, both termination control signals may be asserted simultaneously to effect hard termination within a non-selected module, while a single termination control signal is asserted to effect soft termination (R1 or R2 or, if programmed with the same value, then either of them) within the selected memory module.

FIG. 4 illustrates an alternative embodiment of a memory system 250 having graduated on-die terminations. The memory system 250 includes a memory controller 251 coupled to memory modules 253A and 253B via a multi-drop data path 152 and termination control lines TC1 and TC2 generally as described in reference to FIG. 2. In contrast to FIG. 2, however, each of the memory modules 253 includes a buffer IC 261 that operates as an intermediary between the memory controller 251 and one or more ranks of memory devices 263 ₁-263 _(R). More specifically, the buffer IC 261 includes controller interface to receive signals from and output signals to the memory controller 251 (i.e., coupled to the data path, termination control lines as well as other signal lines (not shown) for conveying command, address and timing signals to/from the memory controller 251), and multiple memory interfaces to transfer signals to and from respective memory ranks 263 (note that, in this regard, the buffer IC 261 may be implemented by multiple separate ICs, each interfacing with a respective one of the memory ranks 263 or a respective subset of the memory ranks). Each of the data paths (and/or other signal paths for conveying command, address and timing signals) coupled between a memory rank 263 and a given memory interface of the buffer IC 261 may be a point-to-point link or and may be singly or doubly terminated (i.e., termination structures coupled to one or both ends) either on die or on the memory module 253. In one embodiment, the controller interface within the buffer IC 261 is implemented in generally the manner described for the individual memory devices within the embodiment of FIG. 2. That is, each buffer IC 261 includes two termination control inputs, TCa and TCb, to enable reception of two independent termination control signals and thus provide for switched connection of one of two graduated termination loads to each high-speed signal line of the data path 152. As in the embodiment of FIG. 2, the termination control line connections between TC1/TC2 and TCa/TCb are reversed in memory module 253A relative to memory module 253B so that, when a termination control signal is asserted on line TC1, it is received via termination control input TCa in memory module 253A and via termination control input TCb in memory module 253B (as discussed above, a separate pair of termination control lines may be provided for memory module instead of a shared pair of polarity-reversed control lines). Similarly, when a termination control signal is asserted on line TC2, it is received via termination control input TCb in memory module 253A and via termination control input TCa in memory module 253B. As mentioned, multiple buffer ICs may be provided to interface with respective ranks or other groupings of memory ICs within a memory module.

Referring to detail view 256, the controller interface within each buffer IC 261 may be implemented by a set of data I/O circuits 157 that are constructed generally as described above in reference to detail view 156 of FIG. 2. That is, each I/O circuit 157 includes a data transceiver structure 159 (e.g., output driver and signal receiver) and a pair of switched termination structures 161 a and 161 b all coupled in parallel to a respective data line of data path 152. Each of the switched termination structures 161 a and 161 b includes a respective load element (R1, R2) coupled to the data line via a corresponding switch element (X1, X2). The data transceivers 159 are coupled to a buffer logic circuit 265 which operates to multiplex (e.g., switchably couple) inbound signals received from the memory controller 251 via transceivers 159 to a selected one of the memory ranks 263 ₁-263 _(R) via a corresponding one of memory interfaces 266 ₁-266 _(R), and to multiplex outbound signals received from one of the memory ranks 263 ₁-263 _(R) to the data transceivers 159 and thus to the memory controller 251.

As in the embodiment of FIG. 2, the switch elements X1 within each of the I/O circuits 157 is coupled in common to termination control input TCa and the switch elements X2 are coupled in common to termination control input TCb. By this arrangement, and by virtue of the reversed connection of the TCa/TCb termination control inputs of memory modules 253A and 253B to termination control lines TC1 and TC2, when a termination control signal is asserted on termination control line TC1, load elements R1 are switchably coupled to respective lines of the data path 152 within memory module 253A, and load elements R2 are switchably coupled to respective lines of the data path 152 within memory module 253B. Similarly, when a termination control signal is asserted on termination control line TC2, load elements R2 are switchably coupled to the data path 152 within memory module 253A and load elements R1 are switchably coupled to the data path 152 within memory module 253B. Accordingly, by programming (or implementing) load elements R1 to have a relatively low impedance (i.e., relatively high load) and load elements R2 to have a relatively high impedance (i.e., relatively low load), load elements R1 may be switchably coupled to the data path 152 to effect hard termination and load elements R2 may be switchably coupled to the data path to effect soft termination. Thus, as shown by the controller operation at 272, during a write operation directed to memory module 253A (memory module A), a termination control signal may be asserted on line TC2 to switchably couple load elements R1 to the data path within memory module 253B, and to switchably couple load elements R1 to the data path within memory module 253A, thus effecting a graduated termination within the selected and non-selected memory modules; a soft termination within the selected memory module and a hard termination within the non-selected memory module.

FIG. 5 illustrates another embodiment of a memory system 300 having graduated on-die terminations. The memory system 300 includes a memory controller 301 coupled to memory modules 303A and 303B via a multi-drop data path 152, as in the embodiments described above, and also via a multi-drop command/address path 302 (CA) which may also be referred to herein as a request path (note that the command/address path may also be provided in the embodiments of FIGS. 2, 3 and 4, but is omitted to avoid obscuring other features of those embodiments). In contrast to the embodiments of FIGS. 2, 3 and 4, however, termination control lines TC1/TC2 are omitted (or at least unused) in favor of snoop logic circuitry within the memory devices 305 of memory modules 303A and 303B. In one embodiment, shown in by detail view 306 of a memory device 305, the snoop logic 315 is included with in the I/O logic and memory core circuitry 310 and is coupled via signal receiver 311 to receive all or a subset of the signals conveyed on command/address path 302. The snoop logic 315 includes circuitry to determine the nature of a requested transaction (e.g., read or write) and to compare a module selector (or module address) conveyed on the command/address path 302 with a module identifier value established for the memory module to determine whether a given memory access transaction is directed to the host memory device 305 (i.e., the memory device in which the snoop logic 315 resides) or to another memory device 305 coupled to the same data slice, and to generate control signals C1 and C2, accordingly (which control signals are supplied to respective switch elements within data I/O circuits 157 implemented as described above in reference to FIG. 2). As shown by the memory operation at 320, if the snoop logic 315 within the memory devices of memory module 303A detects a memory write transaction directed to memory module 303A (i.e., write-enable signal asserted (WE=1) and module selector=module identifier for module 303A), the snoop logic will deassert control signal C1 and assert on control signal C2 to switchably couple load elements R2 (i.e., programmed or implemented by a relatively low-load value to establish a soft termination within the selected module) to the respective lines of data path 152 and switchably decouple load elements R1 from the data path 152. During the same transaction, the snoop logic 315 within the memory devices of memory module 303B will determine that the memory write transaction is directed to another memory module (i.e., memory module A) and, in response, assert terminal control line C2 and deassert control signal C1 to switchably couple load elements R1 to the data path 152 and switchably coupled load elements R2 from the data path 152, thereby establishing a hard termination in the non-selected memory module 303B. When the memory controller issues a memory write command directed to memory module 303B, the snoop logic circuits 315 within memory modules 303A and 303B will detect the reversed roles of the memory modules, with the snoop logic 315 within the memory devices 305 of the non-selected memory module 303A switchably coupling load elements R1 to the data path 152 to effect hard terminations and the snoop logic 315 within the memory devices 305 of the selected memory module 303B switchably coupling load elements R2 to the data path 152 to effect soft terminations.

Note that a module address may be established for the memory module through configuration register programming, production-time programming or configuration (e.g., established by a fuse, anti-fuse or other non-volatile circuit element), pin strapping, etc. Also, with respect to the signals actually snooped by snoop logic 315 to determine whether the host memory device is intended to participate in a given transaction, the snoop logic may evaluate one or all bits of an incoming address field, chip-select signals and/or any other signals that bear on whether the memory device is to respond to the incoming command.

Still referring to FIG. 5, it should be noted that snoop logic circuit 315 may be combined with explicit termination control in alternative embodiments. For example, in one such embodiment, a single termination control line is provided per memory module. A termination control signal is asserted on the termination control line to indicate that a termination should be enabled, while the snoop logic indicates the gradation of the termination to be applied (e.g., soft termination or hard termination). In another alternative embodiment, a finite state machine (FSM) may be provided in place of or in combination with snoop logic circuit 315 to determine the termination value. For example, if a given memory device (or group of memory devices) or buffer IC is expecting to receive data at the time that a termination control signal is asserted (e.g., based on a command, address value or other information received within the memory device or buffer IC a predetermined amount of time prior to transmission of the data or assertion of the control signal), the FSM may signal such expectation and thus elect to apply an appropriate one of multiple termination values. If a single termination control line is provided per module, and the termination control line to a given module is activated but no data is expected, the FSM may elect to apply a different (e.g., higher-load) termination value. A memory device or buffer IC may include an internal state machine for request/command handling purposes (and other control functions), in which case only a relatively small amount of additional logic should be needed within the state machine to select between multiple graduated terminations. Note that a state machine implementation may also be combined with snoop logic instead of or in addition to providing a dedicated termination control line. For example, a FSM within each memory module may determine the termination timing and termination value to be applied within the module according to whether the snoop logic circuit indicates the memory module to be a selected or non-selected memory module for a given transaction. In all such cases, the combination of state machine, dedicated control line input and/or snoop logic circuitry may be provided within a buffer IC as generally described in reference to FIG. 4 instead of within memory ICs.

In an embodiment in which a finite state machine or other control circuit is used instead of or in combination with snoop logic circuit 315 to determine the termination value to be applied during a given transaction, each individual memory devices within each memory rank may include a finite state machine that indicates the operating state of the memory device at any given time, including whether a write or read operation is currently being performed within the memory device. Accordingly, each memory device may respond to assertion of a termination control signal on a shared or dedicated termination control line (i.e., termination control line coupled in common to multiple memory ranks or a dedicated termination control line per memory rank) by effecting hard termination, soft termination or no-termination according to the present device operating state. Alternatively, each memory device may include snoop logic circuitry (e.g., generally as described in reference to FIG. 5) in addition to the finite state machine and may respond to detection of a transaction indicating need for termination control (i.e., the snoop logic, in effect, substituting for dedicated termination control lines) by effecting hard termination, soft termination or no-termination according to the present operating state. FIG. 6 illustrates an exemplary state diagram 350 of a finite state machine that may be applied within a memory device in combination with explicit or implicit termination control detection circuitry (i.e., circuitry coupled to a shared or dedicated termination control line, or snoop logic circuitry) to effect a desired one of multiple, graduated terminations. As shown, the memory devices of a given rank (the state machines of which may generally be operated in lock step) may initially be in an idle operating state 351 in which no rows of the constituent memory banks are activated. Although not specifically shown, the memory devices may transition between the idle state (or any of the other states shown in FIG. 6) and various low power states, initialization states, calibration states, configuration states (i.e., for device configuration operations, including setting of programmable registers), refresh states, etc. that are not specifically shown in FIG. 6. Because no read or write operation is occurring within the memory devices while in the idle state, detection of a termination demand (e.g., detection assertion of a dedicated or shared termination control signal or detection of information on a control and/or address path that indicates a memory read or write transaction) may be inferred to be directed to another memory rank, so that the idle-state memory devices will effect a hard termination (“Hard T”). When an activate command is received within the idle memory rank (i.e., memory rank in which the constituent memory devices are in idle state 351), the constituent memory devices perform respective row activations at the specified row and bank address (and may assume one or more intermediate operating states) and thus transition to active state 353. During the transition to the active state and while in the active state, termination demands may still be inferred to be directed to other memory ranks (i.e., because no read or write operations are occurring within the subject memory rank) so that hard termination is applied as shown. When a write command is received within an activated rank, the constituent memory devices transition to a write state 355 in which write data is delivered to the write-state memory rank and a soft termination (“Soft T”) is applied to improve the signaling characteristics over the data path as described above. Note that other memory ranks may apply hard termination during transfer of the write data in accordance with their operating states. After the write operation is completed (or multiple successive write operations completed), the memory devices of the memory rank may transition to a precharge state (“Prchg”) 359 (e.g., in an auto-precharge mode) or back to the active state 353. In the precharge state 359, the memory devices of the memory rank perform operations to close the open bank and precharge internal signal lines in preparation for a subsequent activation operation. Accordingly, termination demands detected while in the precharge state 359 may be inferred to be directed to other memory ranks so that hard termination is applied as shown. Referring again to active state 353, if a memory read command is received, the memory devices of the memory rank will transition to a read state 357 in which read data is output from the memory devices to a memory controller or other device. Accordingly, during the read state, the memory devices may decouple all termination elements from the data lines on which read data is being driven to avoid undue signal attenuation. As in the write state 355, other memory ranks may apply hard termination during transfer of the read data in accordance with their operating states.

It should be noted that while embodiments and approaches that include or support graduated signal terminations have been described primarily in the context of memory systems, such embodiments and approaches may readily be applied in any signaling system or components thereof in which dynamically-selected, graduated terminations may be beneficial. Also, with respect to memory systems, the nature of the core memory storage elements may vary according to application needs and may include, for example and without limitation, dynamic random access memory (dynamic RAM or DRAM) storage elements, static random access memory (SRAM) storage elements, non-volatile storage elements such as floating-gate transistors within an electrically erasable programmable read only memory (EEPROM or Flash EEPROM) or the like. With regard to implementation of on-die terminations themselves, the load elements may be implemented by virtually any type of passive components (e.g., resistors), active components (e.g., transistors or diodes) or any combination thereof, and the switch elements likewise may be implemented by transistor switches or any other on-die structures that may be used to connect or disconnect a load element from a given node. Also, while the multiple on-die termination elements or circuits have generally been depicted herein as distinct termination circuits, in all such cases two or more termination circuits may be implemented by respective load elements that include shared components. For example, a first load element within a first termination circuit may be implemented by a first set of transistors that are enabled or disabled as a group to effect a first termination impedance, while a second load element within a second termination circuit may include a subset of the first set of transistors that are enabled or disabled as a group to effect a different termination impedance.

Various aspects of embodiments disclosed herein are set forth, for example and without limitation, in the following numbered clauses:

1. A memory module comprising:

a plurality of data inputs to couple to signal lines of an external data path; first and second termination control inputs to receive first and second termination control signals, respectively;

a buffer integrated circuit (IC) having a first interface coupled to the plurality of data inputs and to the first and second control inputs and having a first memory interface that includes a plurality input/output (I/O) nodes; and

a first plurality of memory ICs, each memory IC coupled to a respective subset of the plurality of I/O nodes.

2. The memory module of clause 1 wherein the buffer IC comprises a plurality of termination circuits coupled respectively to the subset of the plurality of data inputs, each termination circuit including a first load element switchably coupled to a corresponding one of the data inputs and a second load element switchably coupled to the corresponding one of the data inputs. 3. The memory module of clause 2 wherein each of the plurality of termination circuits includes a first switch element to switchably couple the first load element to or switchably decouple the first load element from the corresponding one of the data inputs according to the state of a signal received via the first termination control input, and a second switch element to switchably couple the second load element to or switchably decouple the second load from the corresponding one of the data inputs according to the state of a signal received via the second termination control input. 4. The memory module of clause 1 wherein each memory IC of the first plurality of memory ICs comprises an array of dynamic random access memory (DRAM) storage elements. 5. The memory module of clause 1 wherein the buffer IC comprises a second memory interface, and wherein the memory module comprises a second plurality of memory ICs coupled to the second memory interface.

It should also be noted that the various circuits disclosed herein may be described using computer aided design tools and expressed (or represented), as data and/or instructions embodied in various computer-readable media, in terms of their behavioral, register transfer, logic component, transistor, layout geometries, and/or other characteristics. Formats of files and other objects in which such circuit expressions may be implemented include, but are not limited to, formats supporting behavioral languages such as C, Verilog, and VHDL, formats supporting register level description languages like RTL, and formats supporting geometry description languages such as GDSII, GDSIII, GDSIV, CIF, MEBES and any other suitable formats and languages. Computer-readable media in which such formatted data and/or instructions may be embodied include, but are not limited to, non-volatile storage media in various forms (e.g., optical, magnetic or semiconductor storage media) and carrier waves that may be used to transfer such formatted data and/or instructions through wireless, optical, or wired signaling media or any combination thereof. Examples of transfers of such formatted data and/or instructions by carrier waves include, but are not limited to, transfers (uploads, downloads, e-mail, etc.) over the Internet and/or other computer networks via one or more data transfer protocols (e.g., HTTP, FTP, SMTP, etc.).

When received within a computer system via one or more computer-readable media, such data and/or instruction-based expressions of the above described circuits may be processed by a processing entity (e.g., one or more processors) within the computer system in conjunction with execution of one or more other computer programs including, without limitation, net-list generation programs, place and route programs and the like, to generate a representation or image of a physical manifestation of such circuits. Such representation or image may thereafter be used in device fabrication, for example, by enabling generation of one or more masks that are used to form various components of the circuits in a device fabrication process.

In the foregoing description and in the accompanying drawings, specific terminology and drawing symbols have been set forth to provide a thorough understanding of the present invention. In some instances, the terminology and symbols may imply specific details that are not required to practice the invention. For example, the interconnection between circuit elements or circuit blocks may be shown or described as multi-conductor or single conductor signal lines. Each of the multi-conductor signal lines may alternatively be single-conductor signal lines, and each of the single-conductor signal lines may alternatively be multi-conductor signal lines. Signals and signaling paths shown or described as being single-ended may also be differential, and vice-versa. Similarly, signals described or depicted as having active-high or active-low logic levels may have opposite logic levels in alternative embodiments. As another example, circuits described or depicted as including metal oxide semiconductor (MOS) transistors may alternatively be implemented using bipolar technology or any other technology in which logical elements may be implemented. With respect to terminology, a signal is said to be “asserted” when the signal is driven to a low or high logic state (or charged to a high logic state or discharged to a low logic state) to indicate a particular condition. Conversely, a signal is said to be “deasserted” to indicate that the signal is driven (or charged or discharged) to a state other than the asserted state (including a high or low logic state, or the floating state that may occur when the signal driving circuit is transitioned to a high impedance condition, such as an open drain or open collector condition). A signal driving circuit is said to “output” a signal to a signal receiving circuit when the signal driving circuit asserts (or deasserts, if explicitly stated or indicated by context) the signal on a signal line coupled between the signal driving and signal receiving circuits. A signal line is said to be “activated” when a signal is asserted on the signal line, and “deactivated” when the signal is deasserted. Additionally, the prefix symbol “/” attached to signal names indicates that the signal is an active low signal (i.e., the asserted state is a logic low state). A line over a signal name (e.g., ‘ <signal name>’) is also used to indicate an active low signal. The term “coupled” is used herein to express a direct connection as well as a connection through one or more intervening circuits or structures. Integrated circuit device “programming” may include, for example and without limitation, loading a control value into a register or other storage circuit within the device in response to a host instruction and thus controlling an operational aspect of the device, establishing a device configuration or controlling an operational aspect of the device through a one-time programming operation (e.g., blowing fuses within a configuration circuit during device production), and/or connecting one or more selected pins or other contact structures of the device to reference voltage lines (also referred to as strapping) to establish a particular device configuration or operation aspect of the device. The term “exemplary” is used to express an example, not a preference or requirement.

While the invention has been described with reference to specific embodiments thereof, it will be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of the invention. For example, features or aspects of any of the embodiments may be applied, at least where practicable, in combination with any other of the embodiments or in place of counterpart features or aspects thereof. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense. 

What is claimed is:
 1. A method of operation within an integrated circuit memory device, the method comprising: storing a plurality of digital values that specify respective termination impedances; switchably coupling sets of load elements to a data input/output (I/O) to apply termination impedances specified by the digital values, wherein switchably coupling the sets of load elements to the data I/O includes: applying a first termination impedance to the data I/O during an idle state of the memory device, and applying one of two non-equal termination impedances to the data I/O, including applying a first one of the non-equal termination impedances to the data I/O while the memory device receives write data in a memory write operation and applying a second one of the non-equal termination impedances to the data I/O while another memory device receives write data in a memory write operation; and outputting read data via the data I/O in a memory read operation, wherein outputting read data includes switchably coupling to the data I/O at least a portion of the load elements included in the sets of load elements.
 2. The method of claim 1 wherein switchably coupling at least one of the sets of load elements to the data I/O comprises enabling, as a group, a plurality of transistor switches to couple the at least one of the sets of load elements to the data I/O to effect a corresponding one of the termination impedances.
 3. The method of claim 1 wherein the first termination impedance and the second one of the non-equal termination impedances have matching impedance values.
 4. The method of claim 1 further comprising executing an activate operation or a pre-charge operation within the integrated circuit memory device while applying the second one of the non-equal termination impedances and while the other memory device receives write data.
 5. The method of claim 1 wherein the first and second non-equal termination impedances have respective impedance values that are unequal to one another and wherein at least one of the impedance values of the first and second non-equal termination impedances is also unequal to the impedance value of the first termination impedance.
 6. The method of claim 1 wherein the respective sets of load elements comprise a first set of load elements corresponding to the first termination impedance and a second set of load elements corresponding to the first one of the non-equal termination impedances, wherein at least one load element is included in both the first set of load elements and the second set of load elements.
 7. The method of claim 1 wherein at least one load element of the respective sets of load elements is included within an output signal driver, the at least one load element being switchably coupled between the data I/O and a pull-up voltage node or pull-down voltage node when the output signal driver is enabled to drive a signal via the data I/O.
 8. The method of claim 1 wherein at least one of the termination impedances specified by the digital values comprises pull-up elements and pull-down elements within an output driver circuit of the integrated circuit memory device.
 9. The method of claim 8 further comprising switchably coupling the pull-up elements between the data I/O and a pull-up voltage node to transmit a data signal having a first state, and switchably coupling the pull-down elements between the data I/O and a pull-down voltage node to transmit a data signal having a second state.
 10. The method of claim 1 wherein switchably coupling the respective sets of load elements to the data I/O is performed in accordance with operating states of the memory device, and wherein switchably coupling the respective sets of load elements to the data I/O is controlled based on the state of a termination control signal and memory commands received from a memory control component, the operating states of the memory device including the idle state, a memory write state during which the memory device receives the write data, a memory read state during which the memory device transmits the read data, an activate state which precedes a memory read or memory write operation, and a precharge state which follows a memory read or memory write operation.
 11. An integrated circuit memory device comprising: programmable storage circuitry to store a plurality of digital values that specify respective termination impedances; a data input/output (I/O) to be coupled to an external data signaling line; and termination circuitry to switchably couple respective sets of load elements to the data I/O to apply the termination impedances specified by the digital values, the termination circuitry to: apply a first termination impedance to the data I/O during an idle state of the memory device, apply one of two non-equal termination impedances to the data I/O, including applying a first one of the non-equal termination impedances to the data I/O while the memory device receives write data in a memory write operation and applying a second one of the non-equal termination impedances to the data I/O while another memory device receives write data in a memory write operation, and output read data via the data I/O in a memory read operation, including switchably coupling to the data I/O at least a portion of the load elements included in the sets of load elements.
 12. The integrated circuit memory device of claim 11 wherein the termination circuitry comprises circuitry to enable, as a group, a plurality of transistor switches to couple at least one of the sets of load elements to the data I/O to effect a corresponding one of the termination impedances.
 13. The integrated circuit memory device of claim 11 wherein the first termination impedance and the second one of the non-equal termination impedances have matching impedance values.
 14. The integrated circuit memory device of claim 11 further comprising control circuitry to execute an activate operation or a pre-charge operation within the integrated circuit memory device while the termination circuitry applies the second one of the non-equal termination impedances and while the other memory device receives write data.
 15. The integrated circuit memory device of claim 11 wherein the first and second non-equal termination impedances have respective impedance values that are unequal to one another and wherein at least one of the impedance values of the first and second non-equal termination impedances is also unequal to the impedance value of the first termination impedance.
 16. The integrated circuit memory device of claim 11 wherein the respective sets of load elements comprise a first set of load elements corresponding to the first termination impedance and a second set of load elements corresponding to the first one of the non-equal termination impedances, wherein at least one load element is included in both the first set of load elements and the second set of load elements.
 17. The integrated circuit memory device of claim 11 further comprising an output signal driver to transmit the read data via the data I/O, and wherein at least one load element of the respective sets of load elements is included within the output signal driver, the at least one load element being switchably coupled between the data I/O and a pull-up voltage node or pull-down voltage node when the output signal driver is enabled to drive a signal via the data I/O.
 18. The integrated circuit memory device of claim 11 further comprising an output driver circuit to transmit the read data via the data I/O and wherein at least one of the termination impedances specified by the digital values comprises pull-up elements and pull-down elements within the output driver circuit.
 19. The integrated circuit memory device of claim 18 wherein the termination circuitry to switchably couple respective sets of load elements to the data I/O comprises circuitry to (i) switchably couple the pull-up elements between the data I/O and a pull-up voltage node to transmit a data signal having a first state, and (ii) switchably couple the pull-down elements between the data I/O and a pull-down voltage node to transmit a data signal having a second state.
 20. A dynamic random access memory (DRAM) device comprising: a data input/output (I/O); and termination circuitry to switchably couple termination impedances to the data I/O, the termination circuitry including circuitry to: switchably couple to the data input/output (I/O) a termination impedance that corresponds to an idle state of the DRAM; switchably couple to the data I/O each of two non-equal termination impedances that correspond to respective non-idle states of the DRAM, at least one of the non-idle states being a write state in which a write data signal is sampled by the DRAM at the data I/O; and switchably couple to the data I/O load elements included in the termination impedances during a read state of the DRAM to effect transmission of a read data signal via the data I/O. 